EP0108228A2 - Telephone set with low energy consumption - Google Patents

Abstract

In a known circuit of a telephone station with ancillary devices, in which the input circuit (11) of a feed device (10) for ancillary devices is electrically connected in series with the actual listening/speech circuit (6; 7; 8; 9), the carbon microphone has been replaced by the low-impedance secondary winding (8b) of a second speech transformer (8) which bridges a high-impedance part winding (CB) of the primary winding (6a) of a first speech transformer (6) and the line balancing circuit (9), which is electrically connected in series with the former, with respect to direct current. As a result, the feed power consumption of the listening/speech circuit, and thus also that of the telephone station, is greatly reduced. The second speech transformer (8) is additionally used for coupling-in the microphone signal which is generated in a second remote receiver (14) which operates as a microphone, and which is a primary winding (8a) of the second speech transformer (8) via an isolating transformer (18) and a microphone amplifier (13).

Description

Area of application and purpose

The invention relates to a telephone station with low power consumption according to the preamble of claim 1.

Such telephone stations are required in telephone systems in which the telephone exchanges now provide the subscriber loops with a low power and where, in addition to the actual telephone stations, additional devices such as e.g. Coin machines, must be provided with power.

State of the art

It is known from CH-PS 592 989 to use a circuit for such telephone devices which keeps the input circuit power consumption of the power supply of the auxiliary devices as low as possible. This input circuit is electrically connected in series with the actual telephone station.

Task and solution

The invention has for its object to modify a known and standardized telephone station circuit so that its input power consumption is greatly reduced, so that despite the low total loop power available to the subscriber loop, enough power is still available for the additional devices without whose supply devices still require additional effort.

According to the invention, the stated object is achieved by means of the Chen of claim 1 specified features solved.

An embodiment of the invention is shown in the drawing and will be described in more detail below.

• 1 shows a circuit diagram of a telephone station with low power consumption and
• Fig. 2 is a circuit diagram of a microphone amplifier.

The same reference numerals designate the same parts in all figures of the drawing.

description

1 consists of a changeover switch 1, an alternating current alarm 2, an alarm capacitor 3, a number switch impulse opening contact 4, a number switch elevator closing contact 5, a first speech transformer 6, a first telephone 7, a second speech transformer 8, a line simulation 9, a supply device 10 for additional devices, not shown, with an input circuit 11 and a microphone circuit 12, which in turn consists of a microphone amplifier 13, a second remote receiver 14, a load resistor 15, a first diode 16, a second diode 17 and an isolating transformer 18.

The two speech transformers 6 and 8 are the same and each have a primary winding 6a or 8a and a low-resistance secondary winding 6b or 8b. The latter has a first pole A, a second pole B and an intermediate tap C.

The partial winding AC is lower in resistance than the partial winding CB. The isolating transformer 18 has a translation ratio equal to one. The two-pole line simulation 9 consists of a series connection of a first resistor R1 and a parallel connection in turn consisting of a second resistor stood R2 and a capacitor C1.

A first wire 19 of a two-wire telephone line 19; 20 is in the order given via the opening contact of the hook switch 1, the alarm capacitor 3 and the AC alarm clock 2 with the second wire 20 of the telephone line 19; 20 and via the closing contact of the hook switch 1 and the number switch impulse opening contact 4 each connected to the first pole of the primary winding 6a and the first pole of the number switch elevator closing contact 5. The second pole of the latter lies at the first pole of the line simulation 9, the secondary winding 8b and the input of the power supply unit 10. The second pole B of the primary winding 6a leads to the second pole of the line simulation 9 and its intermediate tap C to the second pole of the secondary winding 8b . The secondary winding 6b feeds the first remote handset 7 with two poles, the second remote handset 14 also with two poles the primary winding 18a of the isolating transformer 18 and its secondary winding 18b with two poles, a parallel connection consisting of the two parallel diodes 16 and 17 polarized in the opposite direction and the load resistor 15. The first pole the secondary winding 18b is led to an inverting input and its second pole to a non-inverting input of the microphone amplifier 13, the single-pole output of which feeds the intermediate tap C of the primary winding 8a. The input of the power supply unit 10 consists of the AC voltage input of a Graetz circuit 21 consisting of four diodes, to which an AC short-circuit capacitor 22 is connected in parallel. The second pole of this input is connected to the second wire 20 of the telephone line 19; 20 connected. The two-pole DC voltage output of the Graetz circuit 21, to which the smoothing capacitor 23 is connected in parallel, feeds on the one hand the two-pole input of the DC / DC converter 24, the two-pole output of which in turn forms the two-pole output of the supply device 10, and on the other hand the two-pole supply input of the microphone amplifier 13. The first Pole A of the primary winding 8a lies on the positive pole of the DC voltage output of the Graetz circuit 21 and its second pole B is without connection. The Graetz circuit 21, the AC short-circuit capacitor 22 and the smoothing capacitor 23 form the input circuit 11.

The microphone amplifier 13 according to Fig. 2 consists of an operational amplifier 25, e.g. of the type 301 from National Semiconductor Corporation, Santa Clara, California, an input capacitor 26, a series resistor 27, a feedback resistor 28, a first voltage divider resistor 29, an output capacitor 30, an output resistor 31, a second voltage ladder resistor 32 and a voltage divider capacitor 33. The two the latter are connected in parallel and lie between the non-inverting input of the operational amplifier 25, which is also the non-inverting input of the microphone amplifier 13, and the negative pole of the supply voltage input of the microphone amplifier 13. The inverting input of the latter is via a first RC circuit 34 consisting of the input capacitor 26 and the series resistor 27 are connected to the inverting input of the operational amplifier 25 and to the first pole of the feedback resistor 28, the second pole of which is led to the output of the operational amplifier 25, which via a second RC circuit 35 consisting of the output capacitor 30 and the output resistor 31 is connected to the output of the microphone amplifier 13. The first voltage divider resistor 29 is located between the non-inverting input of the operational amplifier 25 and the positive pole of the supply voltage input of the microphone amplifier 13. The two-pole supply voltage input of the latter is also the two-pole supply voltage input of the operational amplifier 25.

1 corresponds to the known circuit of a telephone station in which the carbon microphone, whose impedance is approximately 230 11, is replaced by the low-impedance secondary winding 8 b of the second speech transformer 8 was and in which the input circuit 11 of the power supply 10 was also electrically connected in series to the hearing / speaking circuit 6; 7; 8th; 9 of the telephone station.

The operation of the unchanged original circuit is known and is therefore only briefly described below. If a call is made to the telephone station from outside, the call signal reaches via the telephone line 19; 20 the opening contact of the hook switch 1 and the alarm capacitor 3 the AC alarm clock 2, the alarm capacitor 3 the supply pond current of the telephone line 19; 20 keeps away from the AC alarm clock 2. If the telephone handset is lifted, the hook switch 1 switches the first wire 19 of the telephone line 19; 20 from the AC alarm clock 2 to the listening / speaking circuit of the telephone station. From this moment on, the received electrical conversation current flows from the first wire 19 via the make contact of the hook switch 1, the number switch input contact 4, the primary winding 6a, the line simulation 9 and the AC short-circuit capacitor 22, which bridges the Graetz circuit 21 in terms of AC, to the second wire 20 the telephone line 19; 20, and the speech signal reaches the first telephone receiver 7 via the first speech transformer 6. The electrical conversation current sent through the telephone station flows via the speech transmission circuit, consisting of the make contact of the hook switch 1, the low-resistance partial winding AC of the primary winding 6a and the AC short-circuit capacitor 22, from the microphone to the telephone line 19; 20. In the modified circuit shown, the second telephone 14, which is the same as the first telephone 7, operates as a microphone and its signal reaches the described transmission circuit of the unchanged original circuit via the isolating transformer 18, the microphone amplifier 13 and the second speech transformer 8. The use of a remote receiver as a microphone has the advantage that the microphone and the remote receiver are the same, but the disadvantage that the available energy is low, so that a microphone amplifier 13 is required. The two diodes 16 and 17 are protective diodes against excessive voltages on Output of the isolating transformer 18, which has the load resistor 15 as a constant load. The input capacitor 26 in the microphone amplifier 13 (see FIG. 2) prevents a DC voltage from appearing at the inverting input of the operational amplifier 25 from its non-inverting input. The output resistor 31, the value of which is approximately equal to 150 u, is used for impedance matching, and the output capacitor 30 isolates the output of the operational amplifier 25 from the primary winding 8a in terms of DC voltage.

The second speech transformer 8 has the dual function of, on the one hand, galvanically isolating the microphone signal into the actual hearing / speaking circuit 6; 7; 8th; 9 to couple the telephone station and, on the other hand, to bridge the high-resistance partial winding CB of the primary winding 6a and the line adapter 9 with the same current with the lowest possible resistance.

The of the telephone line 19; 20 supplied direct current from the telephone station, e.g. 22 mA, flows via the make contact of the hook switch 1, the number switch impulse opening contact 4, the low-resistance partial winding AC of the primary winding 6a, the secondary winding 8b and the Graetz circuit 21. The series shading consisting of the partial winding CB of the primary winding 6a and the line simulation 9 is high-resistance and the direct current flowing in it can be neglected.

The meaning of the Graetz circuit 21 is that its output voltage always has the same polarity, regardless of the direction of current flow of the direct current supply in the telephone line 19; 20th

The operation of the number switch and its elevator closing contact 5 and its pulse opening contact 4 is well known from telephony and is therefore not described in detail since it is not the subject of a patent claim.

• Die Teilwicklung AC der Primärwicklung 6a bzw. 8a besitzt einen Gleichstromwiderstand R_AC, _6a bzw. R_{AC, 8a} von je 50 Ω und derjenige von deren Teilwicklung CB beträgt je 147 Ω. Der Gleichstromwiderstand R_6b bzw. R der Sekundärwicklung 6b bzw. 8b beträgt je 28 Ω. Beim Fliessen eines Speisegleichstroms von I = 22 mA entsteht am Eingang der Fernsprechstelle zwischen den beiden Drähten 19 und 20 ein Gleichspannungsabfall U₁₉, ₂₀ von nur:
  
  wobei V_DC/DC, z.B. 6,5 V, die benötigte Gleichspannung am Eingang des Gleichspannungs/Gleichspannungs-Wandiers 24 und V_GR den Spannungsabfall über die Graetzschaltung 21 darstellt.

Numerical example:

• The partial winding AC of the primary winding 6a or 8a has a DC resistance R _AC , _6a or R _{AC, 8a} of 50 Ω each and that of their partial winding CB is 147 Ω each. The DC resistance R _6b and R of the secondary winding 6b and 8b is 28 Ω each. When a DC supply current of I = 22 mA flows at the entrance to the telephone station between the two wires 19 and 20, a DC voltage drop U ₁₉ , ₂₀ of only:
  
  where V _{DC / DC} , for example 6.5 V, the required DC voltage at the input of the DC / DC converter 24 and V _{GR represents} the voltage drop across the Graetz circuit 21.

wobei R_Mikrofon = 230 Ω der Innenwiderstand eines Kohlemikrofons ist.In contrast, the too high value applies in the original circuit that has not been modified:

where R _microphone = 230 Ω is the internal resistance of a carbon microphone.

Thanks to the replacement of the carbon microphone by the secondary winding 8b, the DC voltage across the actual hearing / speaking circuit 6; 7; 8th; 9 and thus also greatly reduced its power consumption, which in turn reduces that of the entire intercom.

^N8^b wobei N _8a das Wicklungsverhältnis des Transformators 8 und R₃₁ der Wert des Ausgangswiderstandes 31 ist.The AC output impedance at the output of the secondary winding 8b, neglecting the impedance value of the output capacitor 30 and the very low output resistance of the operational amplifier 25:

^N 8 ^b where N _8a the winding ratio of the transformer 8 and R _{31 is} the value of the output resistor 31.

= 73 = 37 dB besitzt, wobei R₂₈ den Wert, z.B. 220 kΩ, des Rückkupplungswiderstandes 28 und R₂₇ denjenigen, z.B. 300 Ω, des Vorwiderstandes 27 darstellt, und dessen Gleichstrom-Verstärkungsfaktor gleich eins ist. Die beiden Spannungsteilerwiderstände 29 und 32, z.B. beide gleich 100 kΩ, bilden einen Spannungsteiler zum Einstellen des Arbeitspunktes des Operationsverstärkers 25, während der Spannungsteilerkondensator 33, z.B. gleich 0,1 µF, den zweiten Spannungsteilerwiderstand 32 wechselstrommässig kurzschtiesst.The circuit of the microphone amplifier 13 according to FIG. 2 is the known operational amplifier circuit of an inverting alternating current amplifier, the alternating current amplification factor of which is the value R ₂₈ / R ₂₇ =

= 73 = 37 dB, where R _{28 is} the value, for example 220 kΩ, of the feedback resistor 28 and R _{27 is} the value, for example 300 Ω, of the series resistor 27, and its DC amplification factor is equal to one. The two voltage divider resistors 29 and 32, for example both equal to 100 kΩ, form a voltage divider for setting the operating point of the operational amplifier 25, while the voltage divider capacitor 33, for example equal to 0.1 μF, short-circuits the second voltage divider resistor 32 in alternating current.

Claims (4)

1. Telephone station with low power consumption, comprising a series connection, consisting of an input circuit of a power supply and a parallel connection of a number switch-elevator closing contact with a series connection, which in turn consists of a line simulation and the primary winding of a first speech transformer, the low-resistance secondary winding of which is connected to a first telephone , characterized in that in addition the low-resistance secondary winding (8b) of a second speech transformer (8) is connected to an intermediate tap (C) of the primary winding (6a) of the first speech transformer (6) in such a way that it has the high-resistance partial winding (CB) of this primary winding ( 6a) and the line simulation (9) bridges, and that the primary winding (8a) of the second speech transformer (8) is fed by a microphone circuit (12). 2. Telephone station according to claim 1, characterized in that the two speech transformers (6, 8) are the same and that only the low-resistance partial winding (AC) of the primary winding (8a) of the second speech transformer (8) is fed by the microphone circuit (12). 3. Telephone station according to claim 1 or 2, characterized in that the microphone circuit (12) contains a second telephone (14) which works as a microphone and which in the specified order via an isolating transformer (18), the output of which is loaded with a parallel connection which consists of a load resistor (15) and two parallel diodes (16, 17) which are polarized in the opposite direction, and .a microphone amplifier (13) is connected to the output of the microphone circuit (12). 4. Telephone station according to claim 3, characterized in that the microphone amplifier (13) is constructed as an inverting AC amplifier by means of an operational amplifier (25),

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